Portable data terminal

ABSTRACT

A portable data terminal that includes a housing and an environmentally responsive device for collecting data about the environment surrounding the housing. The portable data terminal also includes an encoded information reader unit with one or more data collection hardware devices, which can capture data encoded in decodable indicia, e.g., bar codes. In one embodiment, the portable data terminal is configured to operate in a mode that processes the decodable indicia, and the environmental data so as to correlate the information decoded in the decodable indicia with the environmental data.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit of U.S. patent applicationSer. No. 15/372,743 for a Portable Data Terminal filed Dec. 8, 2016 (andpublished Mar. 30, 2017 as U.S. Patent Application Publication No.2017/0091608), now U.S. Pat. No. 9,959,495, which claims the benefit ofU.S. patent application Ser. No. 12/483,470 for a Portable Data Terminalfiled Jun. 12, 2009 (and published Dec. 16, 2010 as U.S. PatentPublication No. 2010/0314443), now U.S. Pat. No. 9,519,814. Each of theforegoing patent applications, patent publications, and patents ishereby incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention is related to devices for decoding decodableindicia, and more particularly, to portable data terminals thatcorrelate environmental data with other data collected by the portabledata terminal.

BACKGROUND OF THE INVENTION

Portable data terminals that are equipped with hardware for readingdecodable indicia are available in multiple varieties. Many of these arefurther configured with additional features, functions, and devices, allof which are combined into a single terminal that is operativelyconfigured to collect, transmit, and receive different types of data.For example, there are many portable data terminals that can collectdata using bar code scanning and imaging hardware, magnetic stripereading hardware, and radio frequency identification tag (“RFID”)reading hardware, among many others. While such hardware permits a widerange of configurations and functionality for the portable dataterminal, this hardware is often not equipped to collect data andinformation about the environment in the immediate vicinity of theterminal device. However, this data can be useful, and particularlybeneficial if it can be correlated to the data encoded in one or more ofthe decodable indicia, or other data that is collected and processed bythe hardware that is already incorporated into the portable dataterminal.

There is therefore a need for a portable data terminal that isconfigured to measure, collect, and store data about the environment. Itis likewise desirable that such a portable data terminal is configuredto process the stored data so as to correlate the environmental datawith the other data, e.g., a bar code, and/or an image.

SUMMARY OF THE INVENTION

There is provided embodiments of a portable data terminal that comprisean environmental sensing device with a sensing portion exposed to, orwith access to the environment in surrounding relation to the portabledata terminal device. Such embodiments are configured to operate in amanner so that the device can collect the environmental data, store theenvironmental data, and correlate the environmental data with otherdata, such as, for example, data that is stored in decodable indicia,which are decoded by, e.g., a bar code reading device.

For purposes of example only, in one embodiment, a portable dataterminal having a housing in surrounding relation to one or morecomponents for reading a decodable indicia, the portable data terminalcomprising a memory, a control circuit communicatively coupled to thememory, an encoded information reader unit responsive to a signal fromthe control circuit, the encoded information reader unit comprising adata collection hardware device selected from one of a bar code readingdevice, an RFID reading device, and a card reading device, an interfacebus communicatively coupled to one or more of the memory, controlcircuit, and the encoded information reader unit, and an environmentallyresponsive device coupled to the interface bus, the environmentallyresponsive device comprising a sensing portion in communication with anenvironment external to the housing in a manner capturing anenvironmental reading for the environment.

In another embodiment, a hand held reader for reading data from theenvironment, the hand held reader comprising a housing comprising anaperture, an environmentally responsive device supportably connected tothe housing in a manner exposing a sensing portion to the environmentproximate the aperture, the sensing portion providing an environmentalreading for the environment, an interface bus communicatively coupled tothe sensing portion, a central processing unit coupled to the interfacebus, the central processing unit providing a signal for capturing theenvironmental reading from the sensing portion, an encoded informationreader unit coupled to the central processing unit, the encodedinformation reader unit comprising a data collection hardware deviceselected from one of a bar code reading device, an RFID reading device,and a card reading device, a memory for storing the environmentalreading and data from the data collection hardware device.

In still another embodiment, a data collection system for a portabledata terminal having a housing with a form factor in surroundingrelation to components of the portable data terminal, the datacollection system comprising an interface bus comprising a two-wireinterface, a temperature sensor coupled to the two-wire interface, thetemperature sensor comprising a sensing portion exposed in a mannerproviding a temperature reading of an environment external to thehousing, a memory for storing the temperature reading, and an encodedinformation reader unit in communication with the memory, the encodedinformation reader unit comprising a data collection hardware deviceselected from one of a bar code reading device, an RFID reading device,and a card reading device, wherein the portable data terminal isoperative in a first sensing mode that correlates data from the datacollection hardware device, and the temperature reading in response toan operator initiated signal.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the presentinvention can be understood in detail, a more particular description ofthe invention briefly summarized above, may be had by reference to theembodiments, some of which are illustrated in the accompanying drawings.It is to be noted, however, that the appended drawings illustrate onlytypical embodiments of this invention and are therefore not to beconsidered limiting of its scope, for the invention may admit to otherequally effective embodiments. Moreover, the drawings are notnecessarily to scale, emphasis generally being placed upon illustratingthe principles of certain embodiments of invention.

Thus, for further understanding of the concepts of the invention,reference can be made to the following detailed description, read inconnection with the drawings in which:

FIG. 1 is a schematic diagram of one example of a portable data terminalthat is made in accordance with concepts of the present invention;

FIG. 2 is a perspective view of another example of a portable dataterminal that is made in accordance with concepts of the presentinvention; and

FIG. 3 is a section view of still another example of a portable dataterminal that is made in accordance with concepts of the presentinvention.

DETAILED DESCRIPTION OF THE INVENTION

With reference to the drawings, in general, and FIGS. 1-3 in particular,there is provided a portable data terminal and implementation thereof,embodiments of which are useful to collect data and information aboutthe environment in surrounding relation to the device, and to correlatethat environmental data with other data, e.g., image data, audio data,and data stored in decodable indicia, which are encoded, decoded, andotherwise captured by the portable data terminal. Devices of the typedisclosed and described herein are particularly configured so as tointerface with the surrounding environment, thus providing a point ofaccess in which to gather the environmental data, e.g., temperaturedata, humidity data, barometer data, and dew point data. This data isstored in memory so that it is available for further processing, suchas, for example, for displaying on a display, performing calculations,graphing, and transmitting, among many other processing paradigms. Suchfunctionality is often included in embodiments of the portable dataterminal because these devices are generally equipped with electricalcomponents that are operatively configured for, e.g., imaging, bar codescanning, picture taking, and card reading.

For example, and as will be discussed in more detail below, portabledata terminals of the type contemplated herein may include electricalcomponents arranged as integrated circuitry. A portion of which can belocated substantially internal to the housing, enclosure, or casement ofthe device. This internal circuitry may include, but is not limited to,processors, volatile memory, and non-volatile memory, all of which cancommunicate via one or more integrated busses. All of these elements areintegrated together to instantiate system architecture (often imprintedon, and/or connected to a printed circuit board), which is designed toexecute instructions, algorithms, and logical operations that instructthe overall functionality of the portable data terminal devices, and inparticular embodiments of the data terminal, the functions discussedimmediately above.

The methods, instructions, algorithms, and logic operations that arehere, and generally conceived to be a sequence of steps or actionsleading to a desired result and may be implemented, or enabled bysoftware, and firmware. While it may prove convenient to discuss suchsoftware as if it were embodied in a single program, mostimplementations will distribute the described functions among discrete(and some not so discrete) pieces of software. These pieces are oftendescribed using such terms as “programs,” “objects,” “functions,”“subroutines,” “libraries,” “.dlls,” “APIs,” and procedures.” One ormore of these may find favor in the present description, although thereis not intention to limit the invention or the described embodiments tothe recited configurations.

For example, software for use in embodiments of the portable dataterminal can include an operating system, such as, but not limited to,WINDOWS CE, WINDOWS MOBIL, WINDOWS XP, LINUX, PALM, SYMBIAN, OSX, andtheir various versions, improvements, and revisions. Likewise thesoftware and the firmware can include applications, and drivers thathave executable instructions compatible with the operating system, andparticularly written so that, when executed, the terminal operates in acertain operating mode, or with certain functionality.

With respect to the software described herein, those having ordinaryskill in the art will recognize that there exist a variety of platformsand languages for creating software for performing methods outlinedherein. Embodiments of the present invention can be implemented usingMICROSOFT VISUAL STUDIO, or any number of varieties of C. The choice ofthe exact platform and language is often dictated by the specifics ofthe actual system constructed, such that what may work for one type ofsystem may not be efficient on another system. It is also note that themethods disclosed and contemplated herein are not limited to beingexecuted as software on a processor or digital signal processor (“DSP”),but can also be implemented in a hardware processor such as would beimplemented with hardware design language (“HDL”) in an applicationspecific integrated circuit (“ASIC”).

By way of non-limiting example, it is seen in FIG. 1 that a high-level,schematic diagram of an example of a portable data terminal 100 isillustrated. Here, it is seen that the portable data terminal 100 caninclude a housing 102 that encapsulates in surrounding relation aninterface bus 104, a control circuit 106 such as may be provided bycentral processing unit (“CPU”) like a microprocessor integrated circuitchip, a memory 108, a user input interface 110, a user output interface112, and an encoded information reader unit 114. The portable dataterminal 100 can also include an environmentally responsive device 116that has a sensing portion 118, which as mentioned above is positionedrelative to the housing 102 so as to capture environmental data for theenvironment exterior to the housing 102 of the portable data terminal100.

The CPU 106 receives data from and outputs data to other sub-systems forstorage, transmission, and additional processing. In the presentexample, the CPU 106 is implemented using any number of off the shelfsolutions. These include, but are not limited to, embedded processors,general purpose processors, or any number of custom solutions includingpre-configured field programmable gate arrays (“FPGAs”), and ASICs.

The memory 108 can include a read only memory device (“ROM”) 120, and arandom access memory device (“RAM”) 122. ROM 118 can be, e.g., an EROMor an EPROM. The memory 108 can also include a storage memory 124 suchas a hard drive, and a flash memory device 126, which may be integratedinto the portable data terminal 100 as it is illustrated in FIG. 1, orin other embodiments it may be a type of replaceable, removable memorydevice such as a flash memory card, a USB memory device, and the like.

Preferably, but not necessarily, the memory 108 can retain numeroustypes of files, including, but not limited to, the operating systemfiles, the application files, the driver files, and configuration filesfor configuring the portable data terminal 100. Typically ones of theconfigurations files have executable instructions that are directed toparticular hardware, integrated circuitry, and/or components of theportable data terminal 100. These include, for example, radiotransceiver devices, card reader devices, and bar code reader devices,examples of which are discussed in more detail below. In one embodiment,the configuration files can be retrieved from the portable data terminal100 by a host computer (not shown) that communicates with the terminal100 via a docking station (not shown), or remotely via wirelesscommunication technology. While not necessary to the generalconstruction and operation of devices of the type consistent with theembodiments of the portable data terminal 100, the host computer isuseful to modify, update, and otherwise change the configuration of theportable data terminal 100. For example, it may be useful to retrievecertain ones of the configuration files from the terminal 100, edit thefiles at the host computer, and then transfer the edited files back tothe terminal 100.

The user input interface 110 can include a pointer controller 128, akeyboard 130, a touch panel 132, and a trigger 134. Exemplary devicesthat can be used for devices of the user input interface 110 aregenerally discussed immediately below. Each of these is implemented aspart of, and often integrated into the housing 102 so as to permit anoperator to input one or more operator initiated commands. Thesecommands may specify, and/or activate certain functions of the portabledata terminal 100. They may also initiate certain ones of theapplications, drivers, and other executable instructions so as to causethe portable data terminal 100 to operate in an operating mode.

Devices that are used for the point controller 128 are generallyconfigured so as to translate the operator initiated command into motionof a virtual pointer provided by a graphical user interface (“GUT”) ofthe operating system of the portable terminal 100. It can includedevices such as a thumbwheel, a roller ball, and a touch pad. In someother configurations, the devices may also include a mouse, or otherauxiliary device that is connected, e.g., via wire, or wirelesscommunication technology, to the portable data terminal 100.

Implementation of the keyboard 130 can be provided using one or morebuttons, which are presented to the operator on the housing 102. Thetouch panel 132 may supplement, or replace the buttons of the keyboard130. For example, one of the GUIs of the operating system may beconfigured to provide one or more virtual icons for display on, e.g., adisplay 136, or as part of another display device on, or connected tothe portable data terminal 100. Such virtual icons (e.g., buttons, andslide bars) are configured so that the operator can select them, e.g.,by pressing or selecting the virtual icon with a stylus (not shown) or afinger (not shown).

The virtual icons can also be used to implement the trigger 134. On theother hand, other devices for use as the trigger 134 may be supportedwithin, or as part of the housing 102. These include, but are notlimited to, a button, a switch, or a similar type of actionable hardwarethat can be incorporated into the embodiments of the portable dataterminal 100. These can be used to activate one or more of the devicesof the portable data terminal, such as the bar code reader discussedbelow.

The user output interface 112 can include the display 136, and an audiodevice 138. Displays of the type suited for use on the portable dataterminal 100 are generally configured to display images, data, and GUIsassociated with the operating system and/or software (and relatedapplications) of the portable data terminal 100. The displays caninclude, but are not limited to, LCD displays, plasma displays, LEDdisplays, among many others and combinations thereof. Although preferredconstruction of the portable data terminal 100 will include devices thatdisplay data (e.g., images, and text) in color, the display that isselected for the display 136 may also display this data in monochrome(e.g., black and white). It may also be desirable that the display 136is configured to display the GUI, and in particular configurations ofthe portable data terminal 100 that display 136 may have an associatedinteractive overlay, like a touch screen overlay. This permits thedisplay 136 to be used as part the GUI so as to permit the operator tointeract with the virtual icons, the buttons, and other implements ofthe GUI to initiate the operator initiated commands, e.g., by pressingon the display 136 with the stylus (not shown) or finger (not shown).

The audio device 138 permits the portable data terminal 100 be used togather, receive, transmit, and convey acoustic signals, e.g., voice,audio, and sounds. Although not provided explicitly in the figuresillustrated and described herein, the audio device 138 may includereceiving and conveying portions. For example, the receiving andconveying portions may be similar to, respectively, a microphone and aspeaker found on telephonic devices, e.g., cellular telephones.

The housing 102 can be constructed so that it has a form, or “formfactor” that can accommodate some, or all of the hardware and devicesmentioned above, and discussed below. The form factor defines theoverall configuration of the housing 102. Suitable form factors that canbe used for the housing 102 include, but are not limited to, cellphones, mobile telephones, personal digital assistants (“PDA”), as wellas other form factors that are sized and shaped to be held, cradled, andsupported by the operator, e.g., in the operator's hand(s). Oneexemplary form factor is illustrated in the embodiment of the portabledata terminal 200 discussed in connection with FIG. 2 below.

The encoded information reader unit 114 can include data collectionhardware 140, which can include, but is not limited to, one or more of abar code reader device 142, an RFID reader device 144, and a card readerdevice 146. The bar code reader device 142 may be provided by, e.g., anIT4XX/5XX Imaging Module of the type available from Hand Held Products,Inc. of Skaneateles Falls, N.Y. The IT4XX/5XX Imaging Module isconfigured with integrated circuitry to capture image data, which can betranslated into visual image data by compatible circuitry and processorscontemplated herein. The IT4XX/5XX Imaging Module is also configuredwith decode out circuitry that provides decoding of a plurality ofdifferent types of bar code symbols and other decodable symbols such asPDF 417, Micro PDF 417, Maxicode, Data Matrix, QR Code, Aztec, AztecMesa, Code 49, UCC Composite, Snowflake, Data Gliffs, Code 39, Code 128,Codabar, UPC, BAN, Interleave 205, RSS, Code 93, Codablock, BC412,Postnet, Planet Code, BPO Forcedate, Canadian Forcedate, Japanese Post,KIX(Dutch Post), OCR A and OCR B.

The RFID reader device 144 is of the type that can wirelessly interactwith RFID transponders, and RFID tags that are compatible with theselected reader device. Exemplary ones of the RFID transponders, andRFID tag, can communicate with the RFID reader device 144 as a passivedevice (limited functionality), and active device (broaderfunctionality). They are generally recognized, and so theirfunctionality is not discussed in detail herein. An example of asuitable device for use as the RFID reader device 144 is provided by aSkyetek SkyeModule series reader and card reader from SkyeTek ofWestminster, Colo.

Suitable card reader devices of type used as the card reader 146 canhave reading and/or writing functionality. This includes, for example,devices compatible with information retrieved from (or encoded in)financial transaction cards, e.g., credit cards, debit cards, giftcards, electronic benefit cards, customer loyalty cards, and the like.It also includes other cards, like, for example, integrated circuitcards that are used as “tokens” for security applications, or as a toolfor use in reconfiguring the data collection tool 100. Other suitabledevices for the card reader 146 may include an integrated circuit card(IC CARD) reader device (not shown), otherwise known as a smart cardreader device.

In one embodiment, the portable data terminal 100 may also include aradio communication interface device unit 148. This may include one ormore radio transceiver devices 150, such as an IEEE 802.11 radiotransceiver device 152, a Bluetooth radio transceiver device 154, aWIMAX radio transceiver device 156, and a cellular radio transceiverdevice 158 compatible with, e.g., GSM and CDMA protocols. Other examplesof devices include, for example, global positioning system (“GPS”)devices, and similar devices that can provide geo-positional,positional, and location information.

Still other embodiments of the portable data terminal 100 may include aserial input/output interface 160, and a power distribution circuit 162that receives power from a variety of different power sources includinga serial power source 164 (e.g., a USB cable), an AC/DC power supply166, and a rechargeable battery 168.

An example of the interface bus 104 is a two-wire interface 170 thatsupports and which can transmit commands to a plurality of integratedcircuits, e.g., the environmentally responsive device 116. Each of theintegrated circuits can be assigned a different two-wire interfaceaddress so that commands and/or parameter data that is intended for aspecific integrated circuit can be sent to that specified integratedcircuit. These commands may originate from the operator as the operatorinitiated command, mentioned above, and also internally as commands andinstructions that are part of, and/or incorporated into the firmware,software, and other executable instructions of the portable dataterminal 100.

In the present example, the two-wire interface 170 includes a signalline 172, or SDA line, and a clocking signal line 174, or SCL line. Eachof which are used, respectively, to transmit data (via signal line 172)and to transmit a clock signal (via the clocking signal line 174). Inone example, each of the signal line 172 and the clocking signal line174 are configured in accordance with a PHILLIPS I²C bus. While thedetails of the I²C bus will not be discussed in detail herein, it iscontemplated that in the interface bus 104 of the present example, thesignal line 172 can carry address information commands, such as, forexample, read and write commands to addressable registers that areinternal to I²C compatible hardware.

Exemplary devices that are used for the environmentally responsivedevice 116 are responsive to one or more environmental factors, such as,for example, temperature, humidity, barometric pressure, and otherfactors typical of the environment about the housing 102 of the portabledata terminal 100. The type and configuration of the environmentallyresponsive device 116 may be selected so that it can be coupled to theinterface bus 104. Generally such devices can be incorporated with thehousing 102, as, for example, an integral (and/or monolithic) part ofthe housing 102.

In other embodiments of the portable data terminal 100, it is alsocontemplated that the housing 102 can include a port, and/or a connector(hereinafter, “a serial bus connector”) that is included with thehousing 102, incorporated into the housing 102, or otherwise disposed onthe housing 102 so as to provide a removable, detachable interface thatcan receive the environmentally responsive device 116. This can include,for example, modules that include all or part of the device 116, whichcan be interchanged onto the device so as to provide one or more of thefunctional responses to the environmental factors discussed immediatelyabove. In one example, the bus serial bus connector is coupled to theinterface bus 104 (e.g., via cabling, and wiring) so as to permit theinterchangeable module to communicate with the interface bus 104.

Certain ones of the device 116 that are used may be compatible with thetwo-wire interface 170, and in one construction of the portable dataterminal 100 the device 116 is compatible with the PHILLIPS I²C bus. Inone embodiment of the portable data terminal 100, the sensing device 118is a temperature sensing device, which measures the temperature of theenvironment around the portable data terminal 100. An example of atemperature sensing device is the TI TMP75 Digital Temperature Sensorwith Two-Wire Interface, manufactured and sold by Texas InstrumentsIncorporated of Dallas, Tex.

In view of the foregoing, various embodiments of the portable dataterminal 100 may be a hand held device, such as data terminal 100, PDAs,or other platform that have data collection hardware 140 withcapabilities to capture and read images, some of which may havedecodable indicia provided therein. PDAs are typically defined as handheld devices (or readers) that are used as a personal organizer, havingmany uses such as reading information bearing the indicia, calculating,use as a clock and calendar, playing computer games, accessing theInternet, sending and receiving electronic messages, facilitatingtelephonic voice communications, use as a radio or stereo, videorecording, recording notes, use as an address book, and use as aspreadsheet. A plurality of buttons and keys may be used to control theoperation of the PDA. This includes the buttons discussed in connectionwith the keyboard 130, and the display 136, as well as other buttons notnecessarily discussed, but that are consistent with the functions, thecapabilities, the control, and the operation of the portable dataterminal 100 overall, and the data collection hardware 140 inparticular.

The portable data terminal 100, like the PDA, may be equipped with theability to query and receive and transmit data, such as firmware via acommunication link. This may be done by radio link or wired link.Upgrading firmware from a host, e.g., the host computer described above,to the PDA (also referred to as uploading or pushing) and duplicatingconfiguration parameters may be performed by reading specific decodableindicia to ensure that the portable data terminal 100 is operating atthe proper revision and have the proper configuration parameters.

FIG. 2 illustrates a perspective view of an example of a portable dataterminal 200 that is constructed in accordance with concepts of thepresent invention. Here, like numerals are used to indicate likecomponents of FIG. 1, except these numerals have been increased by 100.Moreover, because the example that is illustrated has a fully integratedhousing 202, some of the features of the internal circuitry discussed inconnection with FIG. 1 have been removed for clarity. In thisconnection, it is seen that in addition to the housing 202, the portabledata terminal 200 can include a user input interface 210 with a pointercontroller 228, and a keyboard 230, a user output interface 212 that hasa display 236 and an audio device 238, and an environmentally responsivedevice 216 with a sensing portion 218.

It is also seen that the housing 202 can include a front surface 276,side surfaces 278, and a back surface 280, which is located on the sideof the housing 202 that is opposite the front surface 276. The frontsurface 276 has an aperture 282 where the sensing portion 218 ispositioned so as to have access to the environment surrounding thehousing 202. This is, however, only one exemplary configuration of thelocation of the aperture 282. It can be located in different locationsin other embodiments of the portable data terminal 200. That is, theaperture 282 can be located anywhere on the housing 202 in order toaccommodate the sensing portion 218, and to provide suitable access forthe sensing portion 218 so that it can capture the environmental datafrom the environment.

More particularly, and with reference now to the section view of theexample of a portable data terminal 300 that is illustrated in FIG. 3,it is seen that the portable data terminal 300 has a housing 302 thatincorporates an environmentally responsive device 316 with a sensingportion 318, where the housing 302 has a front surface 376 with anaperture 382 that is sized and configured to receive the sensing portion318. The portable data terminal 300 also includes circuit boards 384,and a cable 386 that couples the sensing device 316 to the circuitboards 384. The portable data terminal 300 further includes a mechanicalinterface 388, and a protective cap 390 that is disposed over thesensing portion 318 in the present example of the portable data terminal300.

The circuit boards 384 are generally constructed as printed circuitboards that include one or more of the devices, components, andassemblies discussed in connection with the embodiment illustrated inFIG. 1. That is, the integrated circuitry and other architecture that isneeded to permit the portable data terminal 300 to perform its variousfunctions is constructed as part of one or more of the circuit boards384. This include the interface bus 104 (FIG. 1), and more particularlythe two-wire interface 170 (FIG. 1).

The cable 386 is likewise configured to permit communication of thesensing portion 318 with the circuit boards 384 so that the portabledata terminal 300 can collect the environmental data. Typical cablesthat are used as the cable 386 are constructed so that they can couplethe environmentally responsive device 316 to the interface bus 104 (FIG.1). For example, when coupling with the two-wire interface 170 (FIG. 1),the cable 386 may include a data line (not shown) and a clock line (notshown). These connect, respectively, to the signal line 172 (FIG. 1) andthe clocking signal line 174 (FIG. 1) of the two wire interface 170(FIG. 1). The cable 386 can also include other lines, e.g., power lines,and ground lines, that are selected based on, for example, the type ofsensing apparatus that is used at the sensing portion 318 of theenvironmentally responsive device 316.

By way of non-limiting example, and as it is illustrated in FIG. 3, theaperture 382, the mechanical interface 388, and the protective cap 390are configured in a manner that permits the sensing portion 318 to beexposed to the environment surrounding the housing 302. For example, themechanical interface 388 positions the sensing portion 318 relative tothe aperture 382 so that the sensing portion 318 extends out of thehousing 302. Exemplary mechanical interfaces can include multiple piecedassembles with portions that can receive and secure the sensing portion318 such as, for example, via mechanical fasteners, adhesives, andsnap-type fittings. These may be incorporated integrally as part of thehousing 302, or as separate pieces parts that are assembled and attachedto the housing 302.

The protective cap 390 is typically configured to protect the sensingportion 318, as well as to seal the open portion of the housing 302 atthe aperture 382. It may be desirable that it is constructed ofmaterials that are resistant to damage, such as may occur by dropping,crushing, or attempting to puncture the protective cap 390. Preferably,the materials of construction are also selected so as to promote, orfacilitate the data collection that occurs via the sensing portion 318.For example, if the sensing portion is designed to sense temperature ofthe environment, then the material for the protective cap 390 may havecertain thermal properties that are conducive to transferring thermalenergy from the environment to the sensing portion 318.

As discussed above, the embodiments of the portable data terminals 100,200, 300 are operative in a plurality of operating modes, which can beactivated by the operator via the operator initiated instruction.Generally the operating modes comprise modes that capture environmentaldata, and information from the data collection hardware, as well asother data and information, e.g., time, date, and location. For example,the operating modes may include a mode for collecting environmentaldata, and storing the environmental data in the memory in response tothe decoding of the decodable indicia. Decoding is a term used todescribe the interpretation of the decodable indicia by, e.g., the barcode reader. Information respecting the various reference decodealgorithms is available from various publication standards, such as bythe International Organization (“ISO”).

The operating modes may also include a mode for collecting environmentaldata, where the environmental data is captured at one or moreconfigurable time periods, with or without being initiated by theoperator initiated command. This measured data may be stored in memory.It can also be retrieved from the memory so that it can be displayed onthe display as a graph, in a spreadsheet, or other display methodconsistent with the concepts disclosed herein. In one embodiment of theportable data terminal 100, the operating modes include a mode where theenvironmental data is measured continuously such as, for example, whenthe configurable time period is substantially zero. Here, the measureddata can be stored in memory, and/or displayed on the display of theportable data terminal as a part of, or incorporated into one of theGUIs of the operating system.

Still another operating mode may permit the portable data terminal tocorrelate the environmental data with the information that is decodedfrom the decodable indicia. For example, and discussing animplementation of the portable data terminal in, e.g., a warehousingenvironment, a operator initiate scanning of a bar code of a product viathe operator initiated command (e.g., by pressing a button), and recorddata about the environment in the warehouse at a time contemporaneouslywith bar code scan. The portable data terminal can store the informationfrom the bar code, the environmental data in a file in the memory. Thisfile may have both the information and the environmental data in e.g., acorrelated format. In some embodiments, the information from the barcode, and the environmental data may be stored in separate files, withthe portable data terminal being operatively configured to access, andcorrelate, the information and the environmental data from the separatefiles. In still other embodiments, the portable data terminal may alsorecord the time of the scan, the location of the scan (e.g., via GPS),and store this additional information along with, and/or correlated to,the bar code and environmental data. Examples of other operating modesand functionality as it relates to the environmentally responsive deviceare further disclosed in U.S. Patent Application Publication No.2008/0185432, filed as U.S. patent application Ser. No. 11/669,987, onFeb. 1, 2007 by Caballero et al., and assigned to Hand Held Products,Inc. U.S. Patent Application Publication No. 2008/0185432 isincorporated herein by reference in its entirety.

It is contemplated that numerical values, as well as other values thatare recited herein are modified by the term “about”, whether expresslystated or inherently derived by the discussion of the presentdisclosure. As used herein, the term “about” defines the numericalboundaries of the modified values so as to include, but not be limitedto, tolerances and values up to, and including the numerical value somodified. That is, numerical values can include the actual value that isexpressly stated, as well as other values that are, or can be, thedecimal, fractional, or other multiple of the actual value indicated,and/or described in the disclosure.

While the present invention has been particularly shown and describedwith reference to certain exemplary embodiments, it will be understoodby one skilled in the art that various changes in detail may be effectedtherein without departing from the spirit and scope of the invention asdefined by claims that can be supported by the written description anddrawings. Further, where exemplary embodiments are described withreference to a certain number of elements it will be understood that theexemplary embodiments can be practiced utilizing either less than ormore than the certain number of elements.

The invention claimed is:
 1. A method, comprising: receiving an input totrigger scanning of a decodable indicia; determining location data usinga GPS (Global Positioning System) sensor in response to receiving theinput, wherein the location data is determined contemporaneously withthe scanning of the decodable indicia; operating a device in a firstoperating mode, wherein the device comprises a housing, an audio devicecomprising a speaker for transmitting acoustic signals, and a sensorconnected to the housing in a manner exposing the sensor to anenvironment, and wherein operating the device in the first operatingmode comprises: capturing environmental data at a first configurabletime and a second configurable time that is different from the firstconfigurable time, wherein the environmental data is capturedcontemporaneously with the scanning of the decodable indicia; decodingthe decodable indicia to generate decoded data; correlating the decodeddata, the environmental data at the first configurable time and theenvironmental data at the second configurable time to the location datato generate correlated data; and storing the correlated data in amemory.
 2. The method of claim 1, wherein, in the first operating mode,the location data is determined at the first configurable time and thesecond configurable time.
 3. The method of claim 1, wherein the deviceoperates in a second operating mode which comprises capturing theenvironmental data continuously and storing in the memory.
 4. The methodof claim 1, wherein the environmental data and the decoded data arestored in separate files in the memory.
 5. The method of claim 1,wherein the environmental data comprises temperature data, humiditydata, and dew point data.
 6. A method, comprising: capturing, with adevice and in response to an operator initiated command, an indicia,wherein the device comprises a housing and an audio device comprising aspeaker for transmitting acoustic signals; decoding, with the device,the indicia to generate decoded data; capturing environmental data froma sensor contemporaneously with capturing the indicia, wherein theenvironmental data is stored in a memory; determining a location of thedevice contemporaneously with capturing the indicia; correlating theenvironmental data and the location with the decoded data to generatecorrelated data; and storing the correlated data in the memory.
 7. Themethod of claim 6, wherein contemporaneously capturing the environmentaldata from the sensor comprises capturing the environmental data at afirst configurable time and a second configurable time, and wherein thefirst configurable time is separated from the second configurable timeby a configurable time period.
 8. The method of claim 6, comprising:capturing a first environmental reading; and after a configurable timeperiod from capturing the first environmental reading, capturing asecond environmental reading.
 9. The method of claim 6, wherein storingthe correlated data in memory comprises storing the correlated data inmemory in the device.
 10. The method of claim 6, comprising: receivingan acoustic signal with the audio device and generating audio data,wherein the device comprises the audio device.
 11. The method of claim10, wherein the audio device comprises a microphone.
 12. The method ofclaim 10, wherein the acoustic signals comprise voice, audio, and/orsounds.